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Claims  |
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What is claimed is:
1. An apertureless near field optical microscopy method of measuring the
optical properties of a surface of a sample comprising the steps of:
disposing a tip having an end in proximity to the sample surface;
applying a first dither motion at a first frequency for causing the tip and
sample surface to undergo relative motion toward and away from each other
in a direction substantially normal to the plane of the sample surface;
applying simultaneously a second dither motion at a second frequency for
causing the tip and sample surface to undergo relative motion in a
direction substantially parallel to the plane of the sample surface;
illuminating the end of the tip with optical energy; and
detecting the light scattered from the end of the tip and the sample
surface at a frequency related to said first frequency and said second
frequency for measuring optical properties of the sample surface.
2. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein the amplitude of said first and said second dither motions are
comparable to the measuring resolution.
3. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 2,
wherein the amplitudes of said first and said second dither motions are
both in the range between approximately 0.1 to 1000 Angstroms.
4. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 2,
wherein said first and second frequencies are in the range between
approximately 100 Hz and 1 MHz.
5. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 3,
wherein said first and second frequencies are in the range between
approximately 100 Hz and 1 MHz.
6. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein said frequency related to said first and said second frequency is
the difference between said first and said second frequencies.
7. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein said frequency related to said first and said second frequency is
the sum of said first and said second frequencies.
8. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
further comprising the step of providing a signal responsive to said
detected scattered light for displaying optical properties of the surface
of the sample.
9. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 8,
further comprising the step of scanning the sample relative to the tip.
10. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein the tip is maintained stationary and the sample undergoes both
said dither motions.
11. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein the tip undergoes said first dither motion and the sample
undergoes said second dither motion.
12. An apertureless near field optical microscopy method of measuring
optical properties of a surface of a sample as set forth in claim 1,
wherein said illuminating with optical energy is illuminating by laser
means.
13. An apertureless near field microscope for measuring optical properties
of a surface of a sample comprising:
a tip having an end disposed in proximity to the sample surface;
means for applying a first dither motion at a first frequency for causing
the tip and sample surface to undergo relative motion toward and away from
each other in a direction substantially normal to the plane of the sample
surface;
means for applying a second dither motion at a second frequency for causing
the tip and sample surface to undergo relative motion in a direction
substantially parallel to the plane of the sample surface;
means for illuminating the end of said tip with optical energy, and
detection means for detecting the light scattered from the end of said tip
and the sample surface at a frequency related to said first frequency and
said second frequency for measuring optical properties of the sample
surface.
14. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein the amplitude
of said first and said second dither motions are comparable to the
measuring resolution.
15. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 14, where the amplitudes of
said first and said second dither motions are both in the range between
approximately 0.1 to 1000 Angstroms.
16. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 14, wherein said first and
said second frequencies are in the range between approximately 100 Hz and
1 MHz.
17. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 15, wherein said first and
said second frequencies are in the range between approximately 100 Hz and
1 MHz.
18. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein said detection
means detects the light scattered at a frequency related to the difference
between said first and second frequencies.
19. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein said detection
means detects the light scattered a frequency related to the sum of said
first and second frequencies.
20. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, further comprising
imaging means coupled to said detection means for displaying optical
properties of the surface of the sample.
21. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein said means for
applying a first dither motion moves said tip and said means for applying
a second dither motion moves the sample surface.
22. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein said means for
applying a first dither motion moves the sample surface and means for
applying to second dither motion moves the sample surface while said tip
remains stationary.
23. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, wherein said means for
illuminating is a laser.
24. An apertureless near field microscope for measuring optical properties
of a surface of a sample as set forth in claim 13, further comprising
means for scanning the sample surface relative to said tip.
25. An apertureless near field optical microscope for measuring optical
properties of a surface of a sample comprising:
a tip having an end disposed in proximity to the sample surface;
illumination means for providing a beam of optical energy;
acousto-optic modulation means for receiving said beam of optical energy
and providing a first optical beam and a second optical beam;
beam splitter means for receiving said first beam and splitting a portion
thereof and for receiving and splitting a portion of a backscattered
signal;
quarter wave plate for passing therethrough the split portion of said first
beam and the back scattered signal;
lens means for focussing the beam from said quarter wave plate onto the end
of said tip and for focussing the back scattered signal onto said quarter
wave plate;
beam combiner means for combining the split portion of the back scattered
signal from said beam splitter means and said second optical beam;
detection means for detecting the output of said beam combiner means and
providing an electrical signal responsive thereto;
means for causing a first dither motion at a first frequency for causing
the tip and sample surface to undergo relative motion toward and away from
each other in a direction substantially normal to the plane of sample
surface;
means for causing a second dither motion at a second frequency for causing
the tip and sample surface to undergo relative motion in a direction
substantially parallel to the plane of the sample surface;
means for providing a reference signal at a frequency substantially equal
to the difference between said first and said second frequencies;
amplifier means coupled to receive said reference signal and said
electrical signal for providing an output signal indicative of the optical
properties of the sample surface;
scanning means for causing said sample surface to undergo motion relative
to said tip in a plane substantially parallel to the sample surface, and
display means for imaging optical properties of the sample surface. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to near field optical microscopy, and more
particularly to a method and apparatus which eliminates the requirement
for and hence the optical limitations of an aperture in near field optical
microscopy. As a result, resolution of 1 nm or smaller using visible light
wavelengths is obtainable.
Efforts to date in the art of near field optical microscopy have centered
upon the generation of ultrasmall apertures on transparent tips or flat
surfaces. Such work is described in the article entitled "Optical
Stethoscopy: Image Recording With Resolution g/20" by D. W. Pohl et al,
Appl. Phys. Lett. Vol. 44, No. 7, Apr. 1984, pp. 651 to 653 and in
"Scanning Optical Spectral Microscopy with 500.ANG. Spatial Resolution" by
A. Lewis et al, Biophys. Journal, Vol. 41, 1983, p. 405a.
The ultrasmall apertures generate a sub wavelength source of optical power
which can be used to image surfaces with sub wavelength resolution when
the aperture is scanned in close proximity to the aligned surface. There
are two inherent limitations to the use of such apertures. First, the
structures must be physically built onto a small tip (sub micrometer) when
non-flat surfaces are to be imaged. Constructing such structures have
proven to be technologically challenging. Second, there is a theoretical
limit. In order to achieve the highest resolution, the aperture size
should be reduced toward atomic (on the order of 1 nm) dimensions.
However, the improvement in resolution does not steadily improve as the
aperture size decreases. This effect is due to the aperture material
having a finite absorption length, typically greater than 100 angstroms.
The ultrasmall apertures, therefore, are not useful when the dimension
sought to be resolved approaches the absorption length.
The present invention obviates the requirement of an aperture in near field
optical microscopy by using a metallic or dielectric tip having very small
dimensions, on the order of atomic dimension. Such a tip is found, for
instance, in a scanning thermal profiler, scanning tunneling microscope,
atomic force microscope or the like. A light beam illuminates the tip and
a portion of the light striking the tip scatters and forms local
evanescent fields from the very end region of the tip to the sample
surface which is in proximity to the tip. The evanescent fields very close
to the tip will interact with the surface atoms of the sample. By applying
a first dither motion at a first frequency to the tip in a direction
normal to the plane of the sample surface and applying a second dither
motion at a second frequency to the sample in a direction parallel to
plane of the sample surface, a detector is able to receive surface image
signals at a difference frequency of the two dither frequencies having a
high resolution without the background signal overwhelming the desired
image signal. In an alternative embodiment, the tip is held stationary and
the sample is made to undergo motion in both of the above mentioned
directions each at a different frequency. The essence of the present
invention is the obviating of the requirement of an aperture in a near
field optical microscope and processing of the surface image signals to
remove the adverse affects of the background signal.
SUMMARY OF THE INVENTION
A principal object of the present invention is therefore, the provision in
near field optical microscopy of generating a sub wavelength light source
which is capable of being scanned in close proximity to an object surface
without the use of an aperture.
Another object of the present invention is the provision of a simple
metallic or dielectric tip having very small dimensions to replace the
heretofore used apertures in near field optical microscopy.
A further object of the invention is the provision of dither motion applied
simultaneously to a tip and to the sample for improving image resolution
by elimination of background scattered light.
A still further object of the invention is the provision of dither motion
applied simultaneously to a sample in two orthogonal directions while
maintaining the tip stationary for improving image resolution by
elimination of background scattered light.
Further and still other objects of the invention will become more clearly
apparent when the following description is read in conjunction with the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic representation of the interaction between a tip and a
sample surface;
FIG. 2 is a schematic representation of the tip and the sample surface with
dither motion indicated;
FIG. 3 is a graphical representation of an optical heterodyne signal;
FIG. 4 is a schematic representation of a heterodyne detection system, and
FIG. 5 is a schematic block diagram of a preferred embodiment of the
present invention.
DETAILED DESCRIPTION
A basic limitation in near field optical microscopy is the generation of a
sub wavelength light source which is capable of being scanned in close
proximity to a sample surface. As an alternative to the use of an
aperture, a simple metallic or dielectric tip having very small
dimensions, on the order of atomic dimension, can be used. The
construction and dimensioning of such a tip is well known in art and is
used in devices such as scanning tunneling microscopes. As shown in FIG.
1, incident light indicated by parallel light beams 10 scatter at the end
12 of tip 14 thereby generating local evanescent fields (shown at 16)
which are capable of interacting with the surface 18 of a sample 20 with
high spatial resolution. For example, an ideal conical tip having a single
atom or group of atoms at the very end which is illuminated by a focused
light source, will result in optical evanescent fields diverging from the
tip. The divergent fields will interact with the sample surface on a local
scale. These fields will be scattered by the surface and a portion will
propogate into the far field, where the fields may be detected, providing
a useful signal for measuring the local optical and topographical
properties of the surface with high resolution. Optical properties of the
sample surface capable of being measured include the complex index of
refraction on a localized basis, i.e. the real and imaginary parts of the
dielectric constant. The complex index of refraction determines local
surface reflectivity, local surface transmissivity, and local surface
absorption.
The light source may be a fixed or tunable frequency laser, a CW or pulsed
laser operating in the x-ray, UV, visible, IR or microwave part of the
spectrum, or the like.
A problem with the arrangement above is the fact that the scattering
efficiency of the tip is very small. The light scattered from the surface
and in a non-ideal situation from regions of the tip other than the very
end (background region) would, in general, greatly exceed the light power
reflected from the very end of the tip. The result is that obtaining
useful or desired information in the manner described in conjunction with
FIG. 1 is virtually impossible.
The invention, as shown schematically in FIG. 2, concerns the simultaneous
application of a vibratary or dither motion at a first frequency to the
tip 14 in the direction of double headed arrow 22 along the longitudinal
axis of the tip, in a direction substantially normal to the plane of the
sample surface and dither motion at a second frequency to the sample in
the direction of double headed arrow 24 in a direction substantially
parallel to the plane of the sample surface. As a result, the scattered
light reflected from the tip and the sample surface can be measured at the
difference frequency, i.e. at a frequency equal to the difference of the
first frequency and the second frequency. In a preferred case, the
vibrational amplitudes of both dither motions are chosen to be comparable
to the desired measurement resolution, in the range of approximately 0.1
to 1000 Angstrom, and the tip is disposed in close proximity to the sample
surface. While the amplitudes of both dither motions need not be equal,
both amplitudes should be of the same order of magnitude. In such an
arrangement, the background scattering can be eliminated from the signal
at the difference frequency (f.sub.1 -f.sub.2), thus rendering the desired
reflected light signal easier to detect and measure. The first and second
frequencies are in the range between 100 Hz and 1 MHz. The described
arrangement also obviates the requirement of an aperture for focussing and
detecting light beams.
Methods and apparatus for applying dither motion to the tip at a first
frequency f.sub.1, for instance, by piezoelectric means and by applying
dither motion to a sample at a second frequency to be imaged by
piezoelectric means are well known in the art.
The manner of reducing background signals is illustrated graphically in
FIG. 3 which shows the results of optically mixing the received scattered
field responsive signal in a heterodyne arrangement. Heterodyne
arrangements are known in the art. The simultaneous dither motions of the
tip and the sample produce amplitude and phase modulation of the scattered
light and produce sidebands of the heterodyne carrier.
The carrier signal at frequency f.sub.c is shown as line 26. The frequency
f.sub.c is typically 80 MHz. The sideband signals arising solely from the
tip motion occur at the frequencies f.sub.c +f.sub.1 and f.sub.c -f.sub.1
are shown as lines 28 and 30. The sideband signals arising solely from the
sample motion occur at frequencies f.sub.c +f.sub.2 and f.sub.c -f.sub.2,
shown as lines 32 and 34. The desired signals resulting from the combined
motion of the tip and the sample occur at frequencies f.sub.c +(f.sub.1
-f.sub.2) and f.sub.c -(f.sub.1 -f.sub.2), shown as lines 36 and 38
respectively. It will be obvious to one skilled in the art that additional
signals occur at the frequencies f.sub.c +(f.sub.1 +f.sub.2) and f.sub.c
-(f.sub.1 +f.sub.2) which are not shown. These sum signals are also
useable for measuring optical properties of the sample surface. The
carrier and unwanted sidebands are filtered out using conventional methods
and, in the preferred embodiment, only the difference frequency signals
resulting from the two dither motions is detected.
The resultant detected signal at the difference frequency (f.sub.1
-f.sub.2) (or alternating the sum frequency (f.sub.1 +f.sub.2)) is very
localized at the end of the tip since it is only at that location where
the light will be phase and/or amplitude modulated by both dither motions.
The two dither motions provide a background isolation such that effects of
unwanted scatters decrease as the sixth power of the distance between the
unwanted scatterer and the tip end.
The heterodyne detection of the scattered light beam will provide the means
for shot noise limited detection. In principle, a homodyne system could
also be used if the scattered light from the upper portion of the tip
(away from the end) were combined with the scattered light from the end of
the tip, thereby producing shot noise limited detection.
Referring to FIG. 4, an optical source 40 such as a laser, transmits a beam
of light at a frequency f.sub.o to an acousto-optic modulator 42. A first
portion of the beam entering the acousto-optic modulator 42 is transmitted
through a lens 44 and is focussed on the end 12' of tip 14'. The incident
beam is of a frequency fo+fc where fc is the carrier frequency. The light
beam is forward scattered by the tip and is colimated by lens 46 and
focussed at beam splitter 48. A second portion of the light beam entering
the acousto-optic modulator 42 is transmitted directly to the beam
splitter 48. The two signals are combined at the beam splitter 48 to yield
a light beam at the carrier frequency fc which beam is detected at a pin
photodiode 50 from which an RF carrier signal at frequency fc with
sidebands is provided for further known signal processing.
FIG. 5 is a block diagram of a preferred embodiment for an apertureless
near field optical microscope. A laser 60 transmits an optical energy beam
to an acousto-optic modulator 62. The acousto-optic modulator provides two
output optical beams. The first beam is at a frequency f.sub.o +f.sub.c
and is serially transmitted through a polarizing beam splitter 64, a
quarter wave plate 66 and a colimatting lens 68 to the end of stationary
tip 70 and the sample surface.
The sample is located on a platform (not shown) coupled for movement in
three orthogonal directions by means of an x-piezoelectric drive,
y-piezoelectric drive and z-piezoelectric drive, all shown as reference
numeral 72. The x and y axes are parallel to the surface of the sample and
the z axis is in a direction normal to the sample surface.
In order to measure the entire surface, the sample is made to move in the x
and y axes directions, beneath the stationary tip 70, by means of a scan
drive 74 controlling the x-piezoelectric drive and y-piezoelectric drive.
Oscillator 76 provides a signal to the z-piezoelectric drive at a frequency
w.sub.1 for causing the sample to undergo oscillatory motion in the z-axis
direction at a frequency w.sub.1, toward and away from stationary tip 70
along an axis normal to the sample surface.
Oscillator 78 likewise provides a signal to the x piezoelectric drive at a
frequency w.sub.2 for causing the sample to undergo oscillatory motion at
a frequency w.sub.2 in the x-axis direction, normal to the z-axis motion.
Of course, the signal from oscillator 78 can equally as well be connected
to the y-pizoelectric drive in order to achieve the same results.
The frequencies, w.sub.1 and w.sub.2 , of the signals from oscillators 76
and 78 are in the range from approximately 100 Hz to 1 MHz. The signals
are of such amplitude for causing the respective pizoelectric drive to
cause the sample to undergo motion at an amplitude of approximately 0.1 to
1000 Angstroms in both directions.
The light beam reflection from the tip and sample in a manner as generally
described above in conjunction with FIGS. 2 and 4, is back scattered
through the lens 68, quarter wave plate 66 and polarizing beam splitter
64. The back scattered light signal by virtue of passing through the
described optical system is separated from the light signal from
acousto-optic modulator 62 and is reflected to beam combiner 80. Beam
combiner 80 combines the back scattered light beam from polarizing beam
splitter 64 with the second light beam from acousto-optic modulator 62.
The second light beam from the acousto-optic modulator is at a frequency
f.sub.o. The combined optical signal from beam combiner 80 is detected by
a detector 82 and converted to an electric signal. The output of detector
82 is provided as one input to a lock-in-amplifier 84. The other input to
lock-in aplifier 84 is a reference signal from mixer 86. The reference
signal is preferably at the difference frequency of the two dither
motions, i.e. a frequency equal to w.sub.1 -w.sub.2. Alternatively, the
sum frequency, w.sub.1 +w.sub.2, could also be used.
The lock-in-amplifier 84 provides an output signal indicative of the sample
surface optical properties. The output signal, along with the x-axis and
y-axis position information from scan drive 74 are connected to a display
(not shown) for providing an image or other suitable output of the sample
surface optical properties with atomic or sub-nanometer resolution.
In the event the background signal is not completely eliminated, the low
spatial frequency content of the background signal as the tip scans the
sample can be reduced by analog or digital filtering. The remaining
measured signal variations which have high spatial frequency content still
provide useful information on a very small scale.
Even when the background problem is eliminated by the arrangement described
above, the sensitivity of the measurement remains. Calculation of the
scattering cross section of a single free electron under Thomson
scattering conditions, yields the result that with 10 milliwatts of
optical power focused to a spot of 0.5 micrometers, detection of a single
free electron with a signal-to-noise ratio of 6 can be detected in a 1 Hz
bandwidth. The calculation shows that single atom detection is possible
using the described techniques. Images similar to those of a scanning
tunneling microscope may be possible, except that the optical properties
generate the contrast rather than the electrically accessible electron
states. Using the described technique, optical spectroscopy of sample
surfaces can identify atomic species on an atomic scale at sub-wavelength
resolution.
While there has been described and illustrated a near field optical
microscopy method and apparatus, it will be apparent to those skilled in
the art that modifications and variations are possible without deviating
from the broad principle of the present invention which shall be limited
solely by the scope of the appended claims.
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